Fabrication of uniform and high resolution copper nanowire using intermediate self-assembled monolayers through direct AFM lithography

被引：13

作者：

Kwon, G. ^{[1
]}

Chu, H. ^{[2
]}

Yoo, J. ^{[2
]}

Kim, H. ^{[2
]}

Han, C. ^{[3
]}

Chung, C. ^{[3
]}

Lee, J. ^{[4
]}

Lee, H. ^{[1
,2
,4
]}

机构：

[1] Hanyang Univ, Dept Nanotechnol, Seoul 133791, South Korea

[2] Hanyang Univ, Dept Chem, Seoul 133791, South Korea

[3] Hanyang Univ, Dept Elect & Comp Engn, Seoul 133791, South Korea

[4] Dept Convergence Nanosci, Seoul 136791, South Korea

来源：

NANOTECHNOLOGY | 2012年 / 23卷 / 18期

基金：

新加坡国家研究基金会;

关键词：

SCANNING TUNNELING MICROSCOPE; PROBE LITHOGRAPHY; ELECTRON-BEAM; ANODIZATION LITHOGRAPHY; PALMITIC ACID; NANOFABRICATION; NANOLITHOGRAPHY; PATTERNS; GOLD;

D O I：

10.1088/0957-4484/23/18/185307

中图分类号：

TB3 [工程材料学];

学科分类号：

0805 ; 080502 ;

摘要：

Electrochemical AFM lithography was used to directly fabricate copper nanowires. The copper ions were strongly reduced by a negative sample bias at the point where the AFM tip was localized, and copper metal wires were successfully fabricated following the direction of the electrical field of the bias. A TDA (.) HCl self-assembled monolayer (SAM) was found to play an important role as an intermediate layer for enhancing the capability of high resolution and complete development after the AFM lithographic process. The physical and electrical properties of the wires were analyzed by AFM, EFM, SEM, TEM and I-V measurement. The fabricated copper has promising potential for applications such as masks and interconnectors for nanoelectronic devices.

引用

页数：6

共 32 条

[21] SPONTANEOUSLY ORGANIZED MOLECULAR ASSEMBLIES .4. STRUCTURAL CHARACTERIZATION OF NORMAL-ALKYL THIOL MONOLAYERS ON GOLD BY OPTICAL ELLIPSOMETRY, INFRARED-SPECTROSCOPY, AND ELECTROCHEMISTRY
PORTER, MD
BRIGHT, TB
ALLARA, DL
CHIDSEY, CED
[J]. JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, 1987, 109 (12) : 3559 - 3568
[22] Soft lithography for micro- and nanoscale patterning
Qin, Dong
Xia, Younan
Whitesides, George M.
[J]. NATURE PROTOCOLS, 2010, 5 (03) : 491 - 502
[23] Nanofabrication of electrode arrays by electron-beam and nanoimprint lithographies
Sandison, Mairi E.
Cooper, Jonathan M.
[J]. LAB ON A CHIP, 2006, 6 (08) : 1020 - 1025
[24] Scanning probe lithography .4. Characterization of scanning tunneling microscope-induced patterns in n-alkanethiol self-assembled monolayers
Schoer, JK
Crooks, RM
[J]. LANGMUIR, 1997, 13 (08) : 2323 - 2332
[25] Scanning probe lithography .3. Nanometer-scale electrochemical patterning of Au and organic resists in the absence of intentionally added solvents or electrolytes
Schoer, JK
Zamborini, FP
Crooks, RM
[J]. JOURNAL OF PHYSICAL CHEMISTRY, 1996, 100 (26) : 11086 - 11091
[26] Tseng AA, 2005, SMALL, V1, P924, DOI [10.1002/smll.200500113, 10.1002/smIl.200500113]
[27] Local anodization of permalloy film by atomic force microscope
Uchida, H.
Okada, T.
Shin, K. H.
Inoue, M.
[J]. JOURNAL OF MAGNETISM AND MAGNETIC MATERIALS, 2007, 316 (02) : E67 - E70
[28] Nanolithography and nanochemistry: Probe-related patterning techniques and chemical modification for nanometer-sized devices
Wouters, D
Schubert, US
[J]. ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 2004, 43 (19) : 2480 - 2495
[29] Nanoscale materials patterning and engineering by atomic force microscopy nanolithography
Xie, X. N.
Chung, H. J.
Sow, C. H.
Wee, A. T. S.
[J]. MATERIALS SCIENCE & ENGINEERING R-REPORTS, 2006, 54 (1-2) : 1 - 48
[30] Accurate assembly and size control of cu nanoparticles into nanowires by contact atomic force microscope-based nanopositioning
Yang, De-Quan
Sacher, Edward
[J]. JOURNAL OF PHYSICAL CHEMISTRY C, 2007, 111 (27) : 10105 - 10109

← 1 2 3 4 →